US9011286B2 - Manipulatable epicyclic type clutch device coupled with hybrid power train - Google Patents

Manipulatable epicyclic type clutch device coupled with hybrid power train Download PDF

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US9011286B2
US9011286B2 US13/045,675 US201113045675A US9011286B2 US 9011286 B2 US9011286 B2 US 9011286B2 US 201113045675 A US201113045675 A US 201113045675A US 9011286 B2 US9011286 B2 US 9011286B2
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rotation shaft
power source
rotary kinetic
output
input
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US20120231912A1 (en
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Tai-Her Yang
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Individual
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Priority to US13/045,675 priority Critical patent/US9011286B2/en
Priority to CA2768918A priority patent/CA2768918C/en
Priority to CN201210046048.7A priority patent/CN102678870B/en
Priority to CN201710231205.4A priority patent/CN107269781B/en
Priority to JP2012038839A priority patent/JP6050940B2/en
Priority to CN2012200668226U priority patent/CN202851863U/en
Priority to BR102012004075-1A priority patent/BR102012004075B1/en
Priority to EP12156884.4A priority patent/EP2492542A3/en
Priority to TW101203951U priority patent/TWM440372U/en
Priority to TW101107395A priority patent/TWI626389B/en
Priority to KR1020120024014A priority patent/KR20120104100A/en
Publication of US20120231912A1 publication Critical patent/US20120231912A1/en
Priority to US14/547,423 priority patent/US9897178B2/en
Application granted granted Critical
Publication of US9011286B2 publication Critical patent/US9011286B2/en
Priority to KR1020190011612A priority patent/KR20190015432A/en
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H3/00Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion
    • F16H3/44Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion
    • F16H3/72Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion with a secondary drive, e.g. regulating motor, in order to vary speed continuously
    • F16H3/721Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion with a secondary drive, e.g. regulating motor, in order to vary speed continuously with an energy dissipating device, e.g. regulating brake or fluid throttle, in order to vary speed continuously
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60KARRANGEMENT OR MOUNTING OF PROPULSION UNITS OR OF TRANSMISSIONS IN VEHICLES; ARRANGEMENT OR MOUNTING OF PLURAL DIVERSE PRIME-MOVERS IN VEHICLES; AUXILIARY DRIVES FOR VEHICLES; INSTRUMENTATION OR DASHBOARDS FOR VEHICLES; ARRANGEMENTS IN CONNECTION WITH COOLING, AIR INTAKE, GAS EXHAUST OR FUEL SUPPLY OF PROPULSION UNITS IN VEHICLES
    • B60K6/00Arrangement or mounting of plural diverse prime-movers for mutual or common propulsion, e.g. hybrid propulsion systems comprising electric motors and internal combustion engines ; Control systems therefor, i.e. systems controlling two or more prime movers, or controlling one of these prime movers and any of the transmission, drive or drive units Informative references: mechanical gearings with secondary electric drive F16H3/72; arrangements for handling mechanical energy structurally associated with the dynamo-electric machine H02K7/00; machines comprising structurally interrelated motor and generator parts H02K51/00; dynamo-electric machines not otherwise provided for in H02K see H02K99/00
    • B60K6/20Arrangement or mounting of plural diverse prime-movers for mutual or common propulsion, e.g. hybrid propulsion systems comprising electric motors and internal combustion engines ; Control systems therefor, i.e. systems controlling two or more prime movers, or controlling one of these prime movers and any of the transmission, drive or drive units Informative references: mechanical gearings with secondary electric drive F16H3/72; arrangements for handling mechanical energy structurally associated with the dynamo-electric machine H02K7/00; machines comprising structurally interrelated motor and generator parts H02K51/00; dynamo-electric machines not otherwise provided for in H02K see H02K99/00 the prime-movers consisting of electric motors and internal combustion engines, e.g. HEVs
    • B60K6/42Arrangement or mounting of plural diverse prime-movers for mutual or common propulsion, e.g. hybrid propulsion systems comprising electric motors and internal combustion engines ; Control systems therefor, i.e. systems controlling two or more prime movers, or controlling one of these prime movers and any of the transmission, drive or drive units Informative references: mechanical gearings with secondary electric drive F16H3/72; arrangements for handling mechanical energy structurally associated with the dynamo-electric machine H02K7/00; machines comprising structurally interrelated motor and generator parts H02K51/00; dynamo-electric machines not otherwise provided for in H02K see H02K99/00 the prime-movers consisting of electric motors and internal combustion engines, e.g. HEVs characterised by the architecture of the hybrid electric vehicle
    • B60K6/44Series-parallel type
    • B60K6/445Differential gearing distribution type
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60KARRANGEMENT OR MOUNTING OF PROPULSION UNITS OR OF TRANSMISSIONS IN VEHICLES; ARRANGEMENT OR MOUNTING OF PLURAL DIVERSE PRIME-MOVERS IN VEHICLES; AUXILIARY DRIVES FOR VEHICLES; INSTRUMENTATION OR DASHBOARDS FOR VEHICLES; ARRANGEMENTS IN CONNECTION WITH COOLING, AIR INTAKE, GAS EXHAUST OR FUEL SUPPLY OF PROPULSION UNITS IN VEHICLES
    • B60K6/00Arrangement or mounting of plural diverse prime-movers for mutual or common propulsion, e.g. hybrid propulsion systems comprising electric motors and internal combustion engines ; Control systems therefor, i.e. systems controlling two or more prime movers, or controlling one of these prime movers and any of the transmission, drive or drive units Informative references: mechanical gearings with secondary electric drive F16H3/72; arrangements for handling mechanical energy structurally associated with the dynamo-electric machine H02K7/00; machines comprising structurally interrelated motor and generator parts H02K51/00; dynamo-electric machines not otherwise provided for in H02K see H02K99/00
    • B60K6/20Arrangement or mounting of plural diverse prime-movers for mutual or common propulsion, e.g. hybrid propulsion systems comprising electric motors and internal combustion engines ; Control systems therefor, i.e. systems controlling two or more prime movers, or controlling one of these prime movers and any of the transmission, drive or drive units Informative references: mechanical gearings with secondary electric drive F16H3/72; arrangements for handling mechanical energy structurally associated with the dynamo-electric machine H02K7/00; machines comprising structurally interrelated motor and generator parts H02K51/00; dynamo-electric machines not otherwise provided for in H02K see H02K99/00 the prime-movers consisting of electric motors and internal combustion engines, e.g. HEVs
    • B60K6/42Arrangement or mounting of plural diverse prime-movers for mutual or common propulsion, e.g. hybrid propulsion systems comprising electric motors and internal combustion engines ; Control systems therefor, i.e. systems controlling two or more prime movers, or controlling one of these prime movers and any of the transmission, drive or drive units Informative references: mechanical gearings with secondary electric drive F16H3/72; arrangements for handling mechanical energy structurally associated with the dynamo-electric machine H02K7/00; machines comprising structurally interrelated motor and generator parts H02K51/00; dynamo-electric machines not otherwise provided for in H02K see H02K99/00 the prime-movers consisting of electric motors and internal combustion engines, e.g. HEVs characterised by the architecture of the hybrid electric vehicle
    • B60K6/48Parallel type
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H3/00Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion
    • F16H3/44Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion
    • F16H3/72Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion with a secondary drive, e.g. regulating motor, in order to vary speed continuously
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H3/00Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion
    • F16H3/44Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion
    • F16H3/72Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion with a secondary drive, e.g. regulating motor, in order to vary speed continuously
    • F16H3/724Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion with a secondary drive, e.g. regulating motor, in order to vary speed continuously using external powered electric machines
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H2200/00Transmissions for multiple ratios
    • F16H2200/20Transmissions using gears with orbital motion
    • F16H2200/2002Transmissions using gears with orbital motion characterised by the number of sets of orbital gears
    • F16H2200/2005Transmissions using gears with orbital motion characterised by the number of sets of orbital gears with one sets of orbital gears
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H2200/00Transmissions for multiple ratios
    • F16H2200/20Transmissions using gears with orbital motion
    • F16H2200/2002Transmissions using gears with orbital motion characterised by the number of sets of orbital gears
    • F16H2200/2007Transmissions using gears with orbital motion characterised by the number of sets of orbital gears with two sets of orbital gears
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/60Other road transportation technologies with climate change mitigation effect
    • Y02T10/62Hybrid vehicles
    • Y02T10/6221
    • Y02T10/6239

Definitions

  • the present invention is through an epicyclic gear set (EG 101 ) and a controllable brake device to structure the clutch function, so as to replace the conventional friction type electromagnetic clutch device, and combined with two or more than two of one or more than one types of rotary kinetic power sources to constitute a controllable epicyclic type clutch device coupled with hybrid power train.
  • EG 101 epicyclic gear set
  • a controllable brake device to structure the clutch function, so as to replace the conventional friction type electromagnetic clutch device, and combined with two or more than two of one or more than one types of rotary kinetic power sources to constitute a controllable epicyclic type clutch device coupled with hybrid power train.
  • a friction type electromagnetic clutch device is often installed between conventional automatic or semi-automatic power trains or hybrid power trains for performing engagement or disengagement, so that the power train is enabled to perform various functional operations; however, when the friction type electromagnetic clutch device is in a disengaged state, residual torque may remain, and thereby to cause power loss and system malfunction.
  • the present invention provides a controllable epicyclic type clutch device coupled with hybrid power train structured by using the controllable brake device to manipulate an epicyclic gear set (EG 101 ), in which the power train having the clutch device structured by using the controllable brake device to manipulate the epicyclic gear set (EG 101 ) can be widely applied in a dual rotary kinetic power source or a triple rotary kinetic power source, the structural configuration includes a coaxial in-series structure or a multiple axial in-parallel structure for satisfying the requirement of applied space.
  • FIG. 1 is a schematic structural view showing a rocker arm (A 101 ) and a sleeve type rotation shaft (AS 101 ) driven by a first rotary kinetic power source (P 1 ) and an epicyclic wheel (W 103 ) of an epicyclic gear set (EG 101 ) being combined with a controllable brake device (BK 101 ), and an input wheel (W 102 ) of the epicyclic gear set (EG 101 ) and an output/input end of a rotation shaft (S 102 ) being combined with a second rotary kinetic power source (P 2 ) and an output/input end rotation shaft (S 1026 ), according to one embodiment of the present invention.
  • FIG. 2 is a schematic view showing a first transmission device (T 1 ) being installed between the first rotary kinetic power source (P 1 ) and the controllable brake device (BK 101 ), and the input wheel (W 102 ) of the epicyclic gear set (EG 101 ) and the output/input end of the rotation shaft (S 102 ) being combined with the second rotary kinetic power source (P 2 ) and the output/input end rotation shaft (S 1026 ) shown in FIG. 1 , according to one embodiment of the present invention.
  • FIG. 3 is a schematic view showing a third rotary kinetic power source (P 3 ) being installed between the first rotary kinetic power source (P 1 ) and the controllable brake device (BK 101 ) shown in FIG. 1 , according to one embodiment of the present invention.
  • FIG. 4 is a schematic view showing a third rotary kinetic power source (P 3 ) being installed between the first transmission device (T 1 ) and the controllable brake device (BK 101 ) shown in FIG. 2 , according to one embodiment of the present invention.
  • FIG. 5 is a schematic structural view showing the present invention being structured by the first rotary kinetic power source (P 1 ) and a transmission unit (T 200 ) and the epicyclic gear set (EG 101 ) and a controllable brake device (BK 102 ), and the output wheel (W 102 ) of the epicyclic gear set (EG 101 ) and the output/input end of the rotation shaft (S 102 ) being combined with the second rotary kinetic power source (P 2 ), the epicyclic wheel (W 103 ) of the epicyclic gear set (EG 101 ) being provided for driving the rocker arm (A 101 ) and the sleeve type rotation shaft (AS 101 ), and the sleeve type rotation shaft (AS 101 ) being provided for driving the output/input end rotation shaft (S 1031 ) of the transmission unit (T 200 ), and the other output/input end rotation shaft (S 1032 ) of the transmission unit (T 200 ) being installed with a rotation shaft (S 110 ), according to one
  • FIG. 6 is a schematic view showing the structure in FIG. 5 in which the input wheel (W 101 ) of the epicyclic gear set (EG 101 ) being combined with the rotation shaft (S 101 ) and combined with the rotation shaft (S 1011 ) of the first rotary kinetic power source (P 1 ), the rotation shaft (S 101 ) being combined to an action side of a controllable brake device (BK 103 ), and the other action end of the controllable brake device (BK 103 ) being fixed in the housing (H 100 ), a planetary gear set ( 300 ) being installed between the rotation shaft (S 102 ) combined with the output wheel (W 102 ) of the epicyclic gear set (EG 101 ) and the second rotary kinetic power source (P 2 ), the output/input end of the rotation shaft (S 102 ) combined with the output wheel (W 102 ) of the epicyclic gear set (EG 101 ) being combined with a rocker arm (A 111 ) of a planetary gear set (T 300
  • FIG. 7 is a schematic view showing the second rotary kinetic power source (P 2 ) shown in FIG. 5 being installed at one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ).
  • FIG. 8 is a schematic view showing the structure shown in FIG. 7 in which an epicyclic gear set (EG 201 ) and a controllable brake device (BK 104 ) being installed between one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ) and the second rotary kinetic power source (P 2 ).
  • an epicyclic gear set EG 201
  • BK 104 controllable brake device
  • FIG. 9 is a schematic view showing the structure shown in FIG. 7 in which the third rotary kinetic power source (P 3 ) being installed between the first rotary kinetic power source (P 1 ) and the rotation shaft (S 101 ) combined with the input wheel (W 101 ) of the epicyclic gear set (EG 101 ).
  • FIG. 10 is a schematic view showing the structure shown in FIG. 9 in which the epicyclic gear set (EG 201 ) and the controllable brake device (BK 104 ) being installed between one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ) and the second rotary kinetic power source (P 2 ).
  • the epicyclic gear set (EG 201 ) and the controllable brake device (BK 104 ) being installed between one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ) and the second rotary kinetic power source (P 2 ).
  • a friction type electromagnetic clutch device is often installed between conventional automatic or semi-automatic power trains or hybrid power trains for performing engagement or disengagement, so that the power train is enabled to perform various functional operations; however, when the friction type electromagnetic clutch device is in a disengaged state, residual torque may remain, and thereby to cause power loss and system malfunction.
  • the present invention is through an epicyclic gear set (EG 101 ) and a controllable brake device to structure the clutch function, so as to replace the conventional friction type electromagnetic clutch device, and combined with two or more than two of one or more than one types of rotary kinetic power sources to constitute a controllable epicyclic type clutch device coupled with hybrid power train.
  • EG 101 epicyclic gear set
  • a controllable brake device to structure the clutch function, so as to replace the conventional friction type electromagnetic clutch device, and combined with two or more than two of one or more than one types of rotary kinetic power sources to constitute a controllable epicyclic type clutch device coupled with hybrid power train.
  • the present invention provides a controllable epicyclic type clutch device coupled with hybrid power train structured by using the controllable brake device to manipulate an epicyclic gear set (EG 101 ), in which the power train having the clutch device structured by using the controllable brake device to manipulate the epicyclic gear set (EG 101 ) can be widely applied in a dual rotary kinetic power source or a triple rotary kinetic power source, the structural configuration includes a coaxial in-series structure or a multiple axial in-parallel structure for satisfying the requirement of applied space.
  • FIG. 1 is a schematic structural view showing a rocker arm (A 101 ) and a sleeve type rotation shaft (AS 101 ) driven by a first rotary kinetic power source (P 1 ) and an epicyclic wheel (W 103 ) of an epicyclic gear set (EG 101 ) being combined with a controllable brake device (BK 101 ), and an input wheel (W 102 ) of the epicyclic gear set (EG 101 ) and an output/input end of a rotation shaft (S 102 ) being combined with a second rotary kinetic power source (P 2 ) and an output/input end rotation shaft (S 1026 ), according to one embodiment of the present invention.
  • FIG. 1 it mainly consists of:
  • FIG. 2 is a schematic view showing a first transmission device (T 1 ) being installed between the first rotary kinetic power source (P 1 ) and the controllable brake device (BK 101 ), and the input wheel (W 102 ) of the epicyclic gear set (EG 101 ) and the output/input end of the rotation shaft (S 102 ) being combined with the second rotary kinetic power source (P 2 ) and the output/input end rotation shaft (S 1026 ) shown in FIG. 1 , according to one embodiment of the present invention.
  • FIG. 2 it mainly consists of:
  • FIG. 3 is a schematic view showing a third rotary kinetic power source (P 3 ) being installed between the first rotary kinetic power source (P 1 ) and the controllable brake device (BK 101 ) shown in FIG. 1 , according to one embodiment of the present invention.
  • FIG. 3 it mainly consists of:
  • FIG. 4 is a schematic view showing a third rotary kinetic power source (P 3 ) being installed between the first transmission device (T 1 ) and the controllable brake device (BK 101 ) shown in FIG. 2 , according to one embodiment of the present invention.
  • FIG. 4 it mainly consists of:
  • FIG. 5 is a schematic structural view showing the present invention being structured by the first rotary kinetic power source (P 1 ) and a transmission unit (T 200 ) and the epicyclic gear set (EG 101 ) and a controllable brake device (BK 102 ), and the output wheel (W 102 ) of the epicyclic gear set (EG 101 ) and the output/input end of the rotation shaft (S 102 ) being combined with the second rotary kinetic power source (P 2 ), the epicyclic wheel (W 103 ) of the epicyclic gear set (EG 101 ) being provided for driving the rocker arm (A 101 ) and the sleeve type rotation shaft (AS 101 ), and the sleeve type rotation shaft (AS 101 ) being provided for driving the output/input end rotation shaft (S 1031 ) of the transmission unit (T 200 ), and the other output/input end rotation shaft (S 1032 ) of the transmission unit (T 200 ) being installed with a rotation shaft (S 110 ), according to one
  • FIG. 5 it mainly consists of:
  • FIG. 6 is a schematic view showing the structure in FIG. 5 in which the input wheel (W 101 ) of the epicyclic gear set (EG 101 ) being combined with the rotation shaft (S 101 ) and combined with the rotation shaft (S 1011 ) of the first rotary kinetic power source (P 1 ), the rotation shaft (S 101 ) being combined to an action side of a controllable brake device (BK 103 ), and the other action end of the controllable brake device (BK 103 ) being fixed in the housing (H 100 ), a planetary gear set ( 300 ) being installed between the rotation shaft (S 102 ) combined with the output wheel (W 102 ) of the epicyclic gear set (EG 101 ) and the second rotary kinetic power source (P 2 ), the output/input end of the rotation shaft (S 102 ) combined with the output wheel (W 102 ) of the epicyclic gear set (EG 101 ) being combined with a rocker arm (A 111 ) of a planetary gear set (T 300
  • FIG. 6 it mainly consists of:
  • FIG. 7 is a schematic view showing the second rotary kinetic power source (P 2 ) shown in FIG. 5 being installed at one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ).
  • FIG. 7 it mainly consists of:
  • FIG. 8 is a schematic view showing the structure shown in FIG. 7 in which an epicyclic gear set (EG 201 ) and a controllable brake device (BK 104 ) being installed between one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ) and the second rotary kinetic power source (P 2 ).
  • an epicyclic gear set EG 201
  • BK 104 controllable brake device
  • FIG. 8 it mainly consists of:
  • FIG. 9 is a schematic view showing the structure shown in FIG. 7 in which the third rotary kinetic power source (P 3 ) being installed between the first rotary kinetic power source (P 1 ) and the rotation shaft (S 101 ) combined with the input wheel (W 101 ) of the epicyclic gear set (EG 101 ).
  • FIG. 9 it mainly consists of:
  • FIG. 10 is a schematic view showing the structure shown in FIG. 9 in which the epicyclic gear set (EG 201 ) and the controllable brake device (BK 104 ) being installed between one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ) and the second rotary kinetic power source (P 2 ).
  • the epicyclic gear set (EG 201 ) and the controllable brake device (BK 104 ) being installed between one end of the output/input end rotation shaft (S 110 ) of the transmission unit (T 200 ) and the second rotary kinetic power source (P 2 ).
  • FIG. 10 it mainly consists of:

Abstract

The present invention provides a controllable epicyclic type clutch device coupled with hybrid power train structured by using the controllable brake device to manipulate an epicyclic gear set (EG101), in which the power train having the clutch device structured by using the controllable brake device to manipulate the epicyclic gear set (EG101) can be widely applied in a dual rotary kinetic power source or a triple rotary kinetic power source, the structural configuration includes a coaxial in-series structure or a multiple axial in-parallel structure for satisfying the requirement of applied space.

Description

BACKGROUND OF THE INVENTION
(a) Field of the Invention
The present invention is through an epicyclic gear set (EG101) and a controllable brake device to structure the clutch function, so as to replace the conventional friction type electromagnetic clutch device, and combined with two or more than two of one or more than one types of rotary kinetic power sources to constitute a controllable epicyclic type clutch device coupled with hybrid power train.
(b) Description of the Prior Art
A friction type electromagnetic clutch device is often installed between conventional automatic or semi-automatic power trains or hybrid power trains for performing engagement or disengagement, so that the power train is enabled to perform various functional operations; however, when the friction type electromagnetic clutch device is in a disengaged state, residual torque may remain, and thereby to cause power loss and system malfunction.
SUMMARY OF THE INVENTION
The present invention provides a controllable epicyclic type clutch device coupled with hybrid power train structured by using the controllable brake device to manipulate an epicyclic gear set (EG101), in which the power train having the clutch device structured by using the controllable brake device to manipulate the epicyclic gear set (EG101) can be widely applied in a dual rotary kinetic power source or a triple rotary kinetic power source, the structural configuration includes a coaxial in-series structure or a multiple axial in-parallel structure for satisfying the requirement of applied space.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic structural view showing a rocker arm (A101) and a sleeve type rotation shaft (AS101) driven by a first rotary kinetic power source (P1) and an epicyclic wheel (W103) of an epicyclic gear set (EG101) being combined with a controllable brake device (BK101), and an input wheel (W102) of the epicyclic gear set (EG101) and an output/input end of a rotation shaft (S102) being combined with a second rotary kinetic power source (P2) and an output/input end rotation shaft (S1026), according to one embodiment of the present invention.
FIG. 2 is a schematic view showing a first transmission device (T1) being installed between the first rotary kinetic power source (P1) and the controllable brake device (BK101), and the input wheel (W102) of the epicyclic gear set (EG101) and the output/input end of the rotation shaft (S102) being combined with the second rotary kinetic power source (P2) and the output/input end rotation shaft (S1026) shown in FIG. 1, according to one embodiment of the present invention.
FIG. 3 is a schematic view showing a third rotary kinetic power source (P3) being installed between the first rotary kinetic power source (P1) and the controllable brake device (BK101) shown in FIG. 1, according to one embodiment of the present invention.
FIG. 4 is a schematic view showing a third rotary kinetic power source (P3) being installed between the first transmission device (T1) and the controllable brake device (BK101) shown in FIG. 2, according to one embodiment of the present invention.
FIG. 5 is a schematic structural view showing the present invention being structured by the first rotary kinetic power source (P1) and a transmission unit (T200) and the epicyclic gear set (EG101) and a controllable brake device (BK102), and the output wheel (W102) of the epicyclic gear set (EG101) and the output/input end of the rotation shaft (S102) being combined with the second rotary kinetic power source (P2), the epicyclic wheel (W103) of the epicyclic gear set (EG101) being provided for driving the rocker arm (A101) and the sleeve type rotation shaft (AS101), and the sleeve type rotation shaft (AS101) being provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), and the other output/input end rotation shaft (S1032) of the transmission unit (T200) being installed with a rotation shaft (S110), according to one embodiment of the present invention.
FIG. 6 is a schematic view showing the structure in FIG. 5 in which the input wheel (W101) of the epicyclic gear set (EG101) being combined with the rotation shaft (S101) and combined with the rotation shaft (S1011) of the first rotary kinetic power source (P1), the rotation shaft (S101) being combined to an action side of a controllable brake device (BK103), and the other action end of the controllable brake device (BK103) being fixed in the housing (H100), a planetary gear set (300) being installed between the rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) and the second rotary kinetic power source (P2), the output/input end of the rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) being combined with a rocker arm (A111) of a planetary gear set (T300), an outer annular wheel (W113) of the planetary gear set (T300) being fixed in the housing (H100), a sun wheel (W111) of the planetary gear set (T300) being combined with the second rotary kinetic power source (P2), the epicyclic wheel (W103) of the epicyclic gear set (EG101) being provided for driving the rocker arm (A101) and the sleeve type rotation shaft (AS101), and the sleeve type rotation shaft (AS101) being provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), according to one embodiment of the present invention.
FIG. 7 is a schematic view showing the second rotary kinetic power source (P2) shown in FIG. 5 being installed at one end of the output/input end rotation shaft (S110) of the transmission unit (T200).
FIG. 8 is a schematic view showing the structure shown in FIG. 7 in which an epicyclic gear set (EG201) and a controllable brake device (BK104) being installed between one end of the output/input end rotation shaft (S110) of the transmission unit (T200) and the second rotary kinetic power source (P2).
FIG. 9 is a schematic view showing the structure shown in FIG. 7 in which the third rotary kinetic power source (P3) being installed between the first rotary kinetic power source (P1) and the rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101).
FIG. 10 is a schematic view showing the structure shown in FIG. 9 in which the epicyclic gear set (EG201) and the controllable brake device (BK104) being installed between one end of the output/input end rotation shaft (S110) of the transmission unit (T200) and the second rotary kinetic power source (P2).
 DESCRIPTION OF MAIN COMPONENT SYMBOLS
    • A101
      Figure US09011286-20150421-P00001
      A111
      Figure US09011286-20150421-P00001
      A201: Rocker arm
    • AS101
      Figure US09011286-20150421-P00001
      AS201: Sleeve type rotation shaft
    • BK101
      Figure US09011286-20150421-P00001
      BK102
      Figure US09011286-20150421-P00001
      BK103
      Figure US09011286-20150421-P00001
      BK104: Controllable brake device
    • EG101
      Figure US09011286-20150421-P00001
      EG201: Epicyclic gear set
    • H100: Housing
    • P1: First rotary kinetic power source
    • P2: Second rotary kinetic power source
    • P3: Third rotary kinetic power source
    • S101
      Figure US09011286-20150421-P00001
      S102
      Figure US09011286-20150421-P00001
      S110
      Figure US09011286-20150421-P00001
      S201
      Figure US09011286-20150421-P00001
      S202
      Figure US09011286-20150421-P00001
      S1011
      Figure US09011286-20150421-P00001
      S1012
      Figure US09011286-20150421-P00001
      S1013
      Figure US09011286-20150421-P00001
      S1024
      Figure US09011286-20150421-P00001
      S1025
      Figure US09011286-20150421-P00001
      S1026
      Figure US09011286-20150421-P00001
      S1031
      Figure US09011286-20150421-P00001
      S1032
      Figure US09011286-20150421-P00001
      S1051
      Figure US09011286-20150421-P00001
      S1052: Rotation shaft
    • T1: First transmission device
    • T200: Transmission unit
    • T300: Planetary gear set
    • W101
      Figure US09011286-20150421-P00001
      W201: Input wheel
    • W102
      Figure US09011286-20150421-P00001
      W202: Output wheel
    • W103
      Figure US09011286-20150421-P00001
      W203: Epicyclic wheel
    • W111: Sun wheel
    • W112: Planetary wheel
    • W113: Outer annular wheel
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
A friction type electromagnetic clutch device is often installed between conventional automatic or semi-automatic power trains or hybrid power trains for performing engagement or disengagement, so that the power train is enabled to perform various functional operations; however, when the friction type electromagnetic clutch device is in a disengaged state, residual torque may remain, and thereby to cause power loss and system malfunction.
The present invention is through an epicyclic gear set (EG101) and a controllable brake device to structure the clutch function, so as to replace the conventional friction type electromagnetic clutch device, and combined with two or more than two of one or more than one types of rotary kinetic power sources to constitute a controllable epicyclic type clutch device coupled with hybrid power train.
The present invention provides a controllable epicyclic type clutch device coupled with hybrid power train structured by using the controllable brake device to manipulate an epicyclic gear set (EG101), in which the power train having the clutch device structured by using the controllable brake device to manipulate the epicyclic gear set (EG101) can be widely applied in a dual rotary kinetic power source or a triple rotary kinetic power source, the structural configuration includes a coaxial in-series structure or a multiple axial in-parallel structure for satisfying the requirement of applied space.
The structures and embodiments of the controllable epicyclic type clutch device coupled with hybrid power train are as followings:
FIG. 1 is a schematic structural view showing a rocker arm (A101) and a sleeve type rotation shaft (AS101) driven by a first rotary kinetic power source (P1) and an epicyclic wheel (W103) of an epicyclic gear set (EG101) being combined with a controllable brake device (BK101), and an input wheel (W102) of the epicyclic gear set (EG101) and an output/input end of a rotation shaft (S102) being combined with a second rotary kinetic power source (P2) and an output/input end rotation shaft (S1026), according to one embodiment of the present invention.
As shown in FIG. 1, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK101): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the sleeve type rotation shaft (AS101) or the rocker arm (A101), and the other action side is fixed in the housing (H100);
    • One end of the rotation shaft (S101) is combined with the input wheel (W101) of the epicyclic gear set (EG101), the other end of the rotation shaft (S101) is combined with an output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1), and the rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is served as an output/input end for being combined with an output/input end rotation shaft (S1024) of the second rotary kinetic power source (P2), and the other output/input end rotation shaft (S1025) of the second rotary kinetic power source (P2) is combined with a rotation shaft (S1026) for being served as an output/input end;
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) or the rocker arm (A101) is combined to an action side of the controllable brake device (BK101), the other action side of the controllable brake device (BK101) is fixed in a housing (H100), and through controlling the controllable brake device (BK101) to perform brake locking or releasing, the operations of connecting for transmission or releasing between the rotation shaft (S101) and the rotation shaft (S102) are enabled to be controlled, so as to further control the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2) and the rotation shaft (S1026); for example controlling one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the rotation shaft (S1026).
FIG. 2 is a schematic view showing a first transmission device (T1) being installed between the first rotary kinetic power source (P1) and the controllable brake device (BK101), and the input wheel (W102) of the epicyclic gear set (EG101) and the output/input end of the rotation shaft (S102) being combined with the second rotary kinetic power source (P2) and the output/input end rotation shaft (S1026) shown in FIG. 1, according to one embodiment of the present invention.
As shown in FIG. 2, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK101): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the sleeve type rotation shaft (AS101) or the rocker arm (A101), and the other action side is fixed in the housing (H100);
    • First transmission device (T1): which is constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • The other end of the rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101) is combined with the output/input end rotation shaft (S1012) of the first transmission device (T1), and the output/input end rotation shaft (S1013) at the other end of the first transmission device (T1) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1);
    • The rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined with the output/input end rotation shaft (S1024) of the second rotary kinetic power source (P2), and the output/input end rotation shaft (S1025) at the other end of the second rotary kinetic power source (P2) is combined with the rotation shaft (S1026);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) or the rocker arm (A101) is combined to an action side of the controllable brake device (BK101), the other action side of the controllable brake device (BK101) is fixed in a housing (H100), and through controlling the controllable brake device (BK101) to perform brake locking or releasing, the operations of connecting for transmission or releasing between the rotation shaft (S101) and the rotation shaft (S102) are enabled to be controlled, so as to further control the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2) and the rotation shaft (S1026); for example controlling one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the rotation shaft (S1026).
FIG. 3 is a schematic view showing a third rotary kinetic power source (P3) being installed between the first rotary kinetic power source (P1) and the controllable brake device (BK101) shown in FIG. 1, according to one embodiment of the present invention.
As shown in FIG. 3, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Third rotary kinetic power source (P3): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK101): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the sleeve type rotation shaft (AS101) or the rocker arm (A101), and the other action side is fixed in the housing (H100);
    • The other end of the rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101) is combined to the output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3);
    • The rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined with the output/input end rotation shaft (S1024) of the second rotary kinetic power source (P2), and the output/input end rotation shaft (S1025) at the other end of the second rotary kinetic power source (P2) is combined with the rotation shaft (S1026) for being served as an output/input end;
    • The output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1) is combined with the output/input end rotation shaft (S1052) of the third rotary kinetic power source (P3), and the other output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3) is combined with the rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) or the rocker arm (A101) is combined to an action side of the controllable brake device (BK101), the other action side of the controllable brake device (BK101) is fixed in a housing (H100), and through controlling the controllable brake device (BK101) to perform brake locking or releasing, the operations of connecting for transmission or releasing functions between the rotation shaft (S101) and the rotation shaft (S102) are enabled to be controlled, so as to further control the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2), the third rotary kinetic power source (P3) and the rotation shaft (S1026); for example controlling one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the rotation shaft (S1026), or the first rotary kinetic power source (P1) drives the third rotary kinetic power source (P3) to operate as the power generator function, or the third rotary kinetic power source (P3) is operated as the motor function to actuate and drive the first rotary kinetic power source (P1).
FIG. 4 is a schematic view showing a third rotary kinetic power source (P3) being installed between the first transmission device (T1) and the controllable brake device (BK101) shown in FIG. 2, according to one embodiment of the present invention.
As shown in FIG. 4, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Third rotary kinetic power source (P3): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK101): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the sleeve type rotation shaft (AS101) or the rocker arm (A101), and the other action side is fixed in the housing (H100);
    • First transmission device (T1): constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • The other end of the rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101) is combined to the output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3), the other output/input end rotation shaft (S1052) of the third rotary kinetic power source (P3) is combined with the output/input end rotation shaft (S1012) of the first transmission device (T1), and the other output/input end rotation shaft (S1013) of the first transmission device (T1) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1);
    • The rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined with the output/input end rotation shaft (S1024) of the second rotary kinetic power source (P2), and the other output/input end rotation shaft (S1025) of the second rotary kinetic power source (P2) is combined with the rotation shaft (S1026) for being served as the output/input end;
    • The output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1) is combined with the output/input end rotation shaft (S1013) of the first transmission device (T1), the other output/input end rotation shaft (S1012) of the first transmission device (T1) is combined with the output/input end rotation shaft (S1052) of the third rotary kinetic power source (P3), and the other output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3) is combined with rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) or the rocker arm (A101) is combined to an action side of the controllable brake device (BK101), the other action side of the controllable brake device (BK101) is fixed in a housing (H100), and through controlling the controllable brake device (BK101) to perform brake locking or releasing, the operations of connecting for transmission or releasing functions between the rotation shaft (S101) and the rotation shaft (S102) are enabled to be controlled, so as to further control the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2), the third rotary kinetic power source (P3) and the rotation shaft (S1026); for example controlling one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the rotation shaft (S1026), or the first rotary kinetic power source (P1) drives the third rotary kinetic power source (P3) to operate as the power generator function, or the third rotary kinetic power source (P3) is operated as the motor function to actuate and drive the first rotary kinetic power source (P1).
FIG. 5 is a schematic structural view showing the present invention being structured by the first rotary kinetic power source (P1) and a transmission unit (T200) and the epicyclic gear set (EG101) and a controllable brake device (BK102), and the output wheel (W102) of the epicyclic gear set (EG101) and the output/input end of the rotation shaft (S102) being combined with the second rotary kinetic power source (P2), the epicyclic wheel (W103) of the epicyclic gear set (EG101) being provided for driving the rocker arm (A101) and the sleeve type rotation shaft (AS101), and the sleeve type rotation shaft (AS101) being provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), and the other output/input end rotation shaft (S1032) of the transmission unit (T200) being installed with a rotation shaft (S110), according to one embodiment of the present invention.
As shown in FIG. 5, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK102): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the rotation shaft (S102), and the other action side is fixed in the housing (H100);
    • Transmission unit (T200): constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • One end of the rotation shaft (S101) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1), the other end of the rotation shaft (S101) is combined with the input wheel (W101) of the epicyclic gear set (EG101), the output/input end rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined with the controllable brake device (BK102) and combined with the second rotary kinetic power source (P2), and the epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), and the sleeve type rotation shaft (AS101) is provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), the other output/input end rotation shaft (S1032) of the transmission unit (T200) is provided for driving the output/input end rotation shaft (S110);
    • Through controlling the controllable brake device (BK102) to perform brake locking or releasing, the operations of connecting for transmission or releasing functions between the rotation shaft (S101) and the sleeve type rotation shaft (AS101) are enabled to be controlled, so as to further control the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2) and the rotation shaft (S110); for example controlling one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the rotation shaft (S110).
FIG. 6 is a schematic view showing the structure in FIG. 5 in which the input wheel (W101) of the epicyclic gear set (EG101) being combined with the rotation shaft (S101) and combined with the rotation shaft (S1011) of the first rotary kinetic power source (P1), the rotation shaft (S101) being combined to an action side of a controllable brake device (BK103), and the other action end of the controllable brake device (BK103) being fixed in the housing (H100), a planetary gear set (300) being installed between the rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) and the second rotary kinetic power source (P2), the output/input end of the rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) being combined with a rocker arm (A111) of a planetary gear set (T300), an outer annular wheel (W113) of the planetary gear set (T300) being fixed in the housing (H100), a sun wheel (W111) of the planetary gear set (T300) being combined with the second rotary kinetic power source (P2), the epicyclic wheel (W103) of the epicyclic gear set (EG101) being provided for driving the rocker arm (A101) and the sleeve type rotation shaft (AS101), and the sleeve type rotation shaft (AS101) being provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), according to one embodiment of the present invention.
As shown in FIG. 6, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK102): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the rotation shaft (S102), and the other action side is fixed in the housing (H100);
    • Controllable brake device (BK103): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the rotation shaft (S101), and the other action side is fixed in the housing (H100);
    • Transmission unit (T200): constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • Planetary gear set (T300): constituted by a sun wheel (W111), a planetary wheel (W112), an outer annular wheel (W113) composed of friction wheels or gears, and a shell fixed in the housing (H100), wherein the outer annular wheel (W113) is fixed in the shell then fixed in the housing or directly fixed in the housing, the planetary wheel (W112) is combined with the rocker arm (A111) and combined with the rotation shaft (S102), and the sun wheel (W111) is combined with the output/input end rotation shaft (S1024) of the second rotary kinetic power source (P2);
    • The output/input end rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined to an action side of the controllable brake device (BK102), the other action side of the controllable brake device (BK102) is fixed in the housing (H100), and the other end of the rotation shaft (S102) is combined with the rocker arm (A111) driven by the planetary wheel (W112) of the planetary gear set (T300);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101) and is provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), and the other output/input end rotation shaft (S1032) of the transmission unit (T200) is provided for driving the rotation shaft (S110);
    • The output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1) is combined with the rotation shaft (S101), the rotation shaft (S101) is combined with the input wheel (W101) of the epicyclic gear set (EG101), as well as connected to an action side of the controllable brake device (BK103), and the other action side of the controllable brake device (BK103) is fixed in the housing (H100);
    • Through controlling one or both of the controllable brake device (BK102) and the controllable brake device (BK103) to perform brake locking or releasing, the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2) and the rotation shaft (S110) is enabled to be controlled; for example controlling the operations of connecting for transmission or releasing functions between the rotation shaft (S101) and the sleeve type rotation shaft (AS101) or between the rotation shaft (S102) and the sleeve type rotation shaft (AS101), one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) is further controlled to drive the rotation shaft (S110).
FIG. 7 is a schematic view showing the second rotary kinetic power source (P2) shown in FIG. 5 being installed at one end of the output/input end rotation shaft (S110) of the transmission unit (T200).
As shown in FIG. 7, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK102): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the rotation shaft (S102), and the other action side is fixed in the housing (H100);
    • Transmission unit (T200): constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • One end of the rotation shaft (S101) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1), the other end of the rotation shaft (S101) is combined with the input wheel (W101) of the epicyclic gear set (EG101), the output/input end rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined to an action side of the controllable brake device (BK102), and the other action side of the controllable brake device (BK102) is fixed in the housing (H100);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) is provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), and the other output/input end rotation shaft (S1032) of the transmission unit (T200) is provided for driving the output/input end rotation shaft (S110);
    • One end of the rotation shaft (S110) is combined with the output/input end rotation shaft (S1025) of the second rotary kinetic power source (P2), and the other end of the rotation shaft (S110) is served as an output/input end;
    • Through controlling the controllable brake device (BK102) to perform brake locking or releasing, the operations of connecting for transmission or releasing between the rotation shaft (S101) and the sleeve type rotation shaft (AS101) are enabled to be controlled, so as to further control the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2) and the rotation shaft (S110); for example controlling one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the rotation shaft (S110).
FIG. 8 is a schematic view showing the structure shown in FIG. 7 in which an epicyclic gear set (EG201) and a controllable brake device (BK104) being installed between one end of the output/input end rotation shaft (S110) of the transmission unit (T200) and the second rotary kinetic power source (P2).
As shown in FIG. 8, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Epicyclic gear set (EG201): constituted by an input wheel (W201) and an output wheel (W202) and at least an epicyclic wheel (W203), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S201), the rotation shaft (S202), the rocker arm (A201), the sleeve type rotation shaft (AS201) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK102): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the rotation shaft (S102), and the other action side is fixed in the housing (H100);
    • Controllable brake device (BK104): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the sleeve type rotation shaft (AS201) or the rocker arm (A201), and the other action side is fixed in the housing (H100);
    • Transmission unit (T200): constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • One end of the rotation shaft (S101) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1), the other end of the rotation shaft (S101) is combined with the input wheel (W101) of the epicyclic gear set (EG101), the output/input end rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined to an action side of the controllable brake device (BK102), and the other action side of the controllable brake device (BK102) is fixed in the housing (H100);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) is provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), and the other output/input end rotation shaft (S1032) of the transmission unit (T200) is provided for driving the output/input end rotation shaft (S110);
    • One end of the rotation shaft (S110) is combined with the output/input end rotation shaft (S202) combined with the output wheel (W202) of the epicyclic gear set (EG201), the other output/input end rotation shaft (S201) combined with the input wheel (W201) of the epicyclic gear set (EG201) is combined with the output/input end rotation shaft (S1025) of the second rotary kinetic power source (P2), and the epicyclic wheel (W203) of the epicyclic gear set (EG201) is provided for driving the rocker arm (A201) and the sleeve type rotation shaft (AS201), the sleeve type rotate shaft (AS201) is capable of rotating on the rotation shaft (S201) and is provided for connecting to an action side of the controllable brake device (BK104), the other action side of the controllable brake device (BK104) is fixed in the housing (H100), and the other end of the rotation shaft (S110) is served as an output/input end;
    • Through controlling one or both of the controllable brake device (BK102) and the controllable brake device (BK104) to perform brake locking or releasing, the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2) and the rotation shaft (S110) is enabled to be controlled; for example controlling the operations of connecting for transmission or releasing functions between the rotation shaft (S101) and the sleeve type rotation shaft (AS101) or between the rotation shaft (S201) and the rotation shaft (S202), one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) is controlled to drive the rotation shaft (S110).
FIG. 9 is a schematic view showing the structure shown in FIG. 7 in which the third rotary kinetic power source (P3) being installed between the first rotary kinetic power source (P1) and the rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101).
As shown in FIG. 9, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Third rotary kinetic power source (P3): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK102): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the rotation shaft (S102), and the other action side is fixed in the housing (H100);
    • Transmission unit (T200): constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • One end of the rotation shaft (S101) is combined with the output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3), the rotation shaft (S1052) at the other end of the third rotary kinetic power source (P3) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1), the other end of the rotation shaft (S101) is combined with the input wheel (W101) of the epicyclic gear set (EG101), the output/input end rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined to an action side of the controllable brake device (BK102), and the other action side of the controllable brake device (BK102) is fixed in the housing (H100);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) is provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), and the other output/input end rotation shaft (S1032) of the transmission unit (T200) is provided for driving the output/input end rotation shaft (S110);
    • One end of the rotation shaft (S110) is combined with the output/input end rotation shaft (S1025) of the second rotary kinetic power source (P2), and the other end of the rotation shaft (S110) is served as an output/input end;
    • The rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101) is combined with the output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3), and the other output/input end rotation shaft (S1052) of the third rotary kinetic power source (P3) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1);
    • Through controlling the controllable brake device (BK102) to perform brake locking or releasing, the operations of connecting for transmission or releasing functions between the rotation shaft (S101) and the sleeve type rotation shaft (AS101) are enabled to be controlled, so as to further control the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2), the third rotary kinetic power source (P3) and the rotation shaft (S110); for example controlling one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the rotation shaft (S110), or the first rotary kinetic power source (P1) drives the third rotary kinetic power source (P3) to operate as the power generator function, or the third rotary kinetic power source (P3) is operated as the motor function to actuate and drive the first rotary kinetic power source (P1).
FIG. 10 is a schematic view showing the structure shown in FIG. 9 in which the epicyclic gear set (EG201) and the controllable brake device (BK104) being installed between one end of the output/input end rotation shaft (S110) of the transmission unit (T200) and the second rotary kinetic power source (P2).
As shown in FIG. 10, it mainly consists of:
    • First rotary kinetic power source (P1): constituted by one or more than of one of rotary kinetic power sources capable of generating the rotary kinetic power output, including an internal combustion engine, external combustion engine, Sterling engine, turbine engine, wind-driven blade power set, flow-driven power set, or manual power;
    • Second rotary kinetic power source (P2): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Third rotary kinetic power source (P3): constituted by a rotational electric machine, or constituted by a rotational electric machine combined with a transmission unit, mainly having the motor function for converting the input electric power into the rotary mechanical kinetic energy, as well as having the power generator function for reversely inputting rotary kinetic energy;
    • Epicyclic gear set (EG101): constituted by an input wheel (W101) and an output wheel (W102) and at least an epicyclic wheel (W103), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S101), the rotation shaft (S102), the rocker arm (A101), the sleeve type rotation shaft (AS101) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Epicyclic gear set (EG201): constituted by an input wheel (W201) and an output wheel (W202) and at least an epicyclic wheel (W203), and including through bevel gears engaging with each other, or through bevel friction wheels mutually performing friction transmissions to form an epicyclic gear set function, and structured by the rotation shaft (S201), the rotation shaft (S202), the rocker arm (A201), the sleeve type rotation shaft (AS201) and a bearing, and installed with a shell for being combined with the housing (H100);
    • Controllable brake device (BK102): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the rotation shaft (S102), and the other action side is fixed in the housing (H100);
    • Controllable brake device (BK104): constituted by a brake device controlled by a manual force or mechanical force or hydraulic force or pneumatic force or electromagnetic force, and having two controllable action sides for the operations of a brake locking state for engagement or a releasing state for separation, wherein one of the action sides is connected to the sleeve type rotation shaft (AS201) or the rocker arm (A201), and the other action side is fixed in the housing (H100);
    • Transmission unit (T200): constituted by the automatic, manumatic, semi-automatic, or manual gear shifting device with fixed or variable speed ratios which is further structured by a transmission gear set composed of gears, friction wheels, pulleys and pulley belts, chains and chain wheels, or a planetary type transmission gear set, or an epicyclic type transmission gear set, the CVT, or the hydraulic transmission device;
    • One end of the rotation shaft (S101) is combined with the output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3), the rotation shaft (S1052) at the other end of the third rotary kinetic power source (P3) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1), the other end of the rotation shaft (S101) is combined with the input wheel (W101) of the epicyclic gear set (EG101), the output/input end rotation shaft (S102) combined with the output wheel (W102) of the epicyclic gear set (EG101) is combined to an action side of the controllable brake device (BK102), and the other action side of the controllable brake device (BK102) is fixed in the housing (H100);
    • The epicyclic wheel (W103) of the epicyclic gear set (EG101) is combined with the rocker arm (A101) and combined with the sleeve type rotation shaft (AS101), the sleeve type rotation shaft (AS101) rotates on the rotation shaft (S101), the sleeve type rotation shaft (AS101) is provided for driving the output/input end rotation shaft (S1031) of the transmission unit (T200), and the other output/input end rotation shaft (S1032) of the transmission unit (T200) is provided for driving the output/input end rotation shaft (S110);
    • One end of the rotation shaft (S110) is combined with the output/input end rotation shaft (S202) combined with the output wheel (W202) of the epicyclic gear set (EG201), the other output/input end rotation shaft (S201) combined with the input wheel (W201) of the epicyclic gear set (EG201) is combined with the output/input end rotation shaft (S1025) of the second rotary kinetic power source (P2), and the epicyclic wheel (W203) of the epicyclic gear set (EG201) is provided for driving the rocker arm (A201) and the sleeve type rotation shaft (AS201), the sleeve type rotate shaft (AS201) is capable of rotating on the rotation shaft (S201) and is provided being combined to an action side of the controllable brake device (BK104), the other action side of the controllable brake device (BK104) is fixed in the housing (H100), and the other end of the rotation shaft (S110) is served as an output/input end;
    • The rotation shaft (S101) combined with the input wheel (W101) of the epicyclic gear set (EG101) is combined with the output/input end rotation shaft (S1051) of the third rotary kinetic power source (P3), and the other output/input end rotation shaft (S1052) of the third rotary kinetic power source (P3) is combined with the output/input end rotation shaft (S1011) of the first rotary kinetic power source (P1);
    • Through controlling one or both of the controllable brake device (BK102) and the controllable brake device (BK104) to perform brake locking or releasing, the operation relation between the first rotary kinetic power source (P1), the second rotary kinetic power source (P2), the third rotary kinetic power source (P3) and the rotation shaft (S110) are able to be controlled; for example controlling the operations of connecting for transmission or releasing functions between the rotation shaft (S101) and the sleeve type rotation shaft (AS101) or between the rotation shaft (S201) and the rotation shaft (S202), one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) is controlled to drive the rotation shaft (S110), or the first rotary kinetic power source (P1) drives the third rotary kinetic power source (P3) to operate as the power generator function, or the third rotary kinetic power source (P3) is operated as the motor function to actuate and drive the first rotary kinetic power source (P1).

Claims (5)

The invention claimed is:
1. A controllable epicyclic clutch device coupled with a hybrid power train, comprising:
a first rotary kinetic power source (P1) constituted by at least one of an internal combustion engine, an external combustion engine, a Sterling engine, a turbine engine, a wind-driven blade power set, a flow-driven power set, and a manually driven device, and having an input/output end rotation shaft (S1011);
a second rotary kinetic power source (P2) constituted by at least one of a rotary electric machine and a rotary electric machine with a transmission unit, the rotary electric machine converting input electric power into rotary mechanical kinetic energy and rotary mechanical kinetic energy into electric power, and having at least one of a first input/output end rotation shaft (S1024) and a second input/output end rotation shaft (S1025);
an epicyclic gear set (EG101) including at least one epicyclic wheel (W103) an input wheel (W101), and an output wheel (W102), wherein said at least one epicyclic wheel (W103), input wheel (W101), and output wheel (W102) are bevel gears or bevel friction wheels, said at least one epicyclic wheel engaging both said input wheel (W101) and output wheel (W102);
a first rotation shaft (S101) having a first end connected to and rotatable with said input wheel (W101) and a second end directly or indirectly coupled with the input/output end rotation shaft (S1011) of the first rotary kinetic power source (P1);
a second rotation shaft (S102) having a first end connected to and rotatable with said output wheel (W102);
a rocker arm (A101) on which said epicyclic wheel (W103) is rotatably mounted;
a sleeve type rotation shaft (AS101) extending from the rocker arm (A101), said first rotation shaft (S101) extending through and rotatable relative to the sleeve type rotation shaft (AS101);
a first input/output shaft (S1026) combined with the second input/output end rotation shaft (S1025) of the second rotary kinetic power source (P2)
a controllable brake device (BK101) having a first side fixed to a housing (H100), wherein a second side of the controllable brake device is connected to engage or release one of the rocker arm (A101) and the sleeve type rotation shaft (AS101), thereby locking or releasing said rocker arm (A101) or sleeve type rotation shaft (AS101) to selectively enable the first rotary kinetic power source (P1) to drive the second rotary kinetic power source (P2), to enable the second rotary kinetic power source (P2) to drive the first rotary kinetic power source (P1), and/or to enable one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the first input/output shaft (S1026).
2. A controllable epicyclic clutch device coupled with a hybrid power train as claimed in claim 1, wherein the first input/output end rotation shaft (S1024) of the second rotary kinetic power source (P2) is combined with the second rotary shaft (S102), the second input/output end rotation shaft (1025) of the second rotary kinetic power source (P2) is combined with a input/output rotation shaft (1026) of the controllable epicyclic clutch device, and the controllable brake device (BK101) selectively engages or releases one of the rocker arm (A101) and the sleeve type rotation shaft (AS101), thereby locking or releasing said rocker arm (A101) or sleeve type rotation shaft (AS101) to selectively enable the first rotary kinetic power source (P1) to drive the second rotary kinetic power source (P2), to enable the second rotary kinetic power source (P2) to drive the first rotary kinetic power source (P1), and/or to enable one or both of the first rotary kinetic power source (P1) and the second rotary kinetic power source (P2) to drive the input/output shaft (S1026).
3. A controllable epicyclic clutch device coupled with a hybrid power train as claimed in claim 1, further comprising a first transmission device (T1) having a first side input/output rotation shaft (S1012) and a second side input/output rotation shaft (S1013), the first side input/output rotation shaft (S1012) being connected to the first rotation shaft (S101) and the second side input/output rotation shaft (S1013) being connected to the input/output end rotation shaft (S1011) of the first rotary kinetic energy power source (P1), said first transmission device (T1) being one of an automatic, manumatic, semi-automatic, and manual gear shifting device with a fixed or variable speed ratio and a transmission gear set that includes at least one transmission component selected from a gear, friction wheel, belt and pulley, chain wheel and chain, planetary gear set, epicyclic gear set, continuously variable transmission (CVT), and hydraulic transmission device.
4. A controllable epicyclic clutch device coupled with a hybrid power train as claimed in claim 1, further comprising a third rotary kinetic power source (P3) constituted by at least one of a rotary electric machine and a rotary electric machine with a transmission unit, the rotary electric machine converting input electric power into rotary mechanical kinetic energy and rotary mechanical kinetic energy into electric power, and having a first side rotation shaft (S1051) and a second input/output end rotation shaft (S1052), the first side input/output rotation shaft (S1051) being connected to the first rotation shaft (S101) and the second side input/output rotation shaft (S1052) being connected to the input/output end rotation shaft (S1011) of the first rotary kinetic energy power source (P1), wherein locking or releasing of said rocker arm (A101) or sleeve type rotation shaft (AS101) by the controllable brake device (BK101) selectively enables the first rotary kinetic power source (P1) and/or the second rotary kinetic power source (P2) to drive the third rotary kinetic power source (P3) to operate as a generator, to enable the third rotary kinetic power source (P3) to operate as a motor to drive the first rotary kinetic power source (P1) and/or the second rotary kinetic power source (P2), and/or to enable any combination of the first rotary kinetic power source (P1), the third rotary kinetic power source (P3), and the second rotary kinetic power source (P2) to drive the input/output shaft (S1026).
5. A controllable epicyclic clutch device coupled with a hybrid power train as claimed in claim 4, further comprising a first transmission device (T1) having a first side input/output rotation shaft (S1012) and a second side input/output rotation shaft (S1013), the first side input/output rotation shaft (S1012) being connected to the first side rotation shaft (S1052) of the third rotary kinetic power source (P3) and the second side input/output rotation shaft (S1013) being connected to the input/output end rotation shaft (S1011) of the first rotary kinetic energy power source (P1), said first transmission device (T1) being one of an automatic, manumatic, semi-automatic, and manual gear shifting device with a fixed or variable speed ratio and a transmission gear set that includes at least one transmission component selected from a gear, friction wheel, belt and pulley, chain wheel and chain, planetary gear set, epicyclic gear set, continuously variable transmission (CVT), and hydraulic transmission device.
US13/045,675 2011-02-24 2011-03-11 Manipulatable epicyclic type clutch device coupled with hybrid power train Active US9011286B2 (en)

Priority Applications (13)

Application Number Priority Date Filing Date Title
US13/045,675 US9011286B2 (en) 2011-03-11 2011-03-11 Manipulatable epicyclic type clutch device coupled with hybrid power train
CA2768918A CA2768918C (en) 2011-02-24 2012-02-23 Clutch device structured with controllable epicycle gear set and applied power train thereof
EP12156884.4A EP2492542A3 (en) 2011-02-24 2012-02-24 Clutch device structured with controllable epicycle gear set and applied power train thereof
JP2012038839A JP6050940B2 (en) 2011-02-24 2012-02-24 Clutch device with controllable epicyclic gear train
CN2012200668226U CN202851863U (en) 2011-02-24 2012-02-24 Controllable turnover wheel group clutch device and application power system
BR102012004075-1A BR102012004075B1 (en) 2011-02-24 2012-02-24 STRUCTURED CLUTCH DEVICE WITH CONTROLLABLE EPICYCLOIDAL GEAR SET AND APPLIED POWER PACKAGE THEREOF
CN201210046048.7A CN102678870B (en) 2011-02-24 2012-02-24 Clutch device structured with controllable epicycle gear set and applied power train thereof
CN201710231205.4A CN107269781B (en) 2011-02-24 2012-02-24 Controllable epicyclic gear set clutch device and applied power system
TW101203951U TWM440372U (en) 2011-03-11 2012-03-06 Clutch device structured with controllable epicycle gear set and applied power train thereof
TW101107395A TWI626389B (en) 2011-03-11 2012-03-06 Clutch device structured with controllable epicycle gear set and applied power train thereof
KR1020120024014A KR20120104100A (en) 2011-03-11 2012-03-08 Clutch device structured with controllable epicycle gear set and applied power train thereof
US14/547,423 US9897178B2 (en) 2011-03-11 2014-11-19 Manipulatable epicyclic type clutch device coupled with hybrid power train
KR1020190011612A KR20190015432A (en) 2011-03-11 2019-01-30 Clutch device structured with controllable epicycle gear set and applied power train thereof

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US8696504B2 (en) * 2011-01-07 2014-04-15 Tai-Her Yang Dual power driving system with epicycle gear sets transmitted in series
US20120231911A1 (en) * 2011-03-11 2012-09-13 Tai-Her Yang Power train having manipulatable epicyclic type clutch device
JP6220231B2 (en) * 2013-11-08 2017-10-25 積水化学工業株式会社 Microbial fuel cell

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US20010016532A1 (en) * 1999-12-28 2001-08-23 Hu-Yong Jung Transmission for hybrid electric vehicle
US20030078134A1 (en) * 2001-10-22 2003-04-24 Toyota Jidosha Kabushiki Kaisha Hybrid-vehicle drive system and operation method with a transmission
US7736266B2 (en) * 2007-07-25 2010-06-15 National Taipei University Of Technology Vehicle's active electrically controlled non-step speed change mechanism
US20120232729A1 (en) * 2011-03-11 2012-09-13 Tai-Her Yang Hybrid power train having epicyclic type clutch device

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